A Uniform Random-Lattice Tail Bound for the SVP Kissing-Profile Parameter

Abstract

A recent SICOMP paper on classical and quantum algorithms for the shortest vector problem introduced a lattice-dependent parameter \(γ(L)\), bounded universally in the exponential sense by \(20.402n+o(n)\), and conjectured that this parameter is \(2o(n)\) for most lattices. We prove the Haar--Siegel random-lattice version in a stronger, dimension-uniform form. Let \(Xn=SLn()/SLn()\), let \(μn\) be its invariant probability measure, and let \(γ(L)=r1 NL(rλ1(L))/rn\), where \(NL(R)\) counts nonzero vectors of \(L\) of Euclidean norm at most \(R\). For every \(n3\) and every \(T>0\), \[ μn\L∈ Xn:γ(L)>T\ C T-1 \] with an absolute constant \(C\). Consequently, for every sequence \(an∞\), \(γ(Ln) an\) with \(μn\)-probability tending to one; in particular \(γ(Ln)=2o(n)\) with high probability. In the product model of independent Haar--Siegel lattices, \(γ(Ln) ( n)\) eventually almost surely. The proof uses Rogers's second-moment estimate only through a dyadic self-normalization argument around the random scale \(λ1(L)\).